AMBER and CHARMM Force Fields Inconsistently Portray the Microscopic Details of Phosphorylation

Vymětal, Jiří; Jurásková, Veronika; Vondrášek, Jiřı́

doi:10.1021/acs.jctc.8b00715

Cited by 26 publications

(58 citation statements)

References 84 publications

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“…Given the critical roles of protein phosphorylation in intracellular regulation, the development of appropriate force fields for the accurate modeling of the structural effects of post-translational modifications has attracted considerable interest, as well as the recognition that current force fields are insufficient for accurate modeling of the structural effects of phosphorylation. [65][66][67][68][69][70][71][72] The work herein provides important structural constraints to allow the improved modeling of the effects of protein Ser and Thr phosphorylation.…”

Section: Discussionmentioning

confidence: 99%

An Inherent Structural Difference Between Serine and Threonine Phosphorylation: Phosphothreonine Prefers an Ordered, Compact, Cyclic Conformation

Pandey

Ganguly

Sinha

et al. 2020

Preprint

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Phosphorylation and dephosphorylation of proteins by kinases and phosphatases are central to cellular responses and function. The structural effects of serine and threonine phosphorylation were examined in peptides and in proteins, by circular dichroism, NMR spectroscopy, bioinformatics analysis of the PDB, small-molecule X-ray crystallography, and computational investigations. Phosphorylation of both serine and threonine residues induces substantial conformational restriction in their physiologically more important dianionic forms.Threonine exhibits a particularly strong disorder-to-order transition upon phosphorylation, with dianionic phosphothreonine preferentially adopting a cyclic conformation with restricted φ (φ ~ -60˚) stabilized by three noncovalent interactions: a strong intraresidue phosphate-amide hydrogen bond, an n→π* interaction between consecutive carbonyls, and an n→σ* interaction between the phosphate Oγ lone pair and the antibonding orbital of C-Hβ that restricts the χ 2 side chain conformation. Proline is unique among the canonical amino acids for its covalent cyclization on the backbone. Phosphothreonine can mimic proline's backbone cyclization via noncovalent interactions. The preferred torsions of dianionic phosphothreonine are φ,ψ = polyproline helix or α-helix (φ ~ -60˚); χ 1 = g -; χ 2 = eclipsed C-H/O-P bonds. This structural signature is observed in diverse proteins, including the activation loops of protein kinases and protein-protein interactions. In total, these results suggest a structural basis for the differential use and evolution of threonine versus serine phosphorylation sites in proteins, with serine phosphorylation typically inducing smaller, rheostat-like changes, versus threonine phosphorylation promoting larger, step function-like switches, in proteins.

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Section: Discussionmentioning

confidence: 99%

An Inherent Structural Difference Between Serine and Threonine Phosphorylation: Phosphothreonine Prefers an Ordered, Compact, Cyclic Conformation

Pandey

Ganguly

Sinha

et al. 2020

Preprint

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“…All-atom explicit solvent simulations readily incorporate post-translationally modified amino acids (32)(33)(34)(35)(36) and have been used to probe the contacts leading to phase separation (37,38). However, the ability of atomistic force fields to accurately capture the properties of IDRs depends strongly on parameterization (39,40). Additionally, simulations of sufficiently long length and timescales to predict phase-separation behavior (e.g., saturation concentration) are beyond current computational capability for fully atomistic simulations with explicit water.…”

Section: Introductionmentioning

confidence: 99%

A predictive coarse-grained model for position-specific effects of post-translational modifications

Perdikari

Jovic

Dignon

et al. 2021

Biophysical Journal

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“…[47][48][49][50][51] The validation of phosphorylated amino acid parameters by comparing simulation predictions to experiment is lacking in the literature, in contrast to the case of the canonical amino acids. A recent article by Vymětal et al 52 has pointed out inconsistencies in calculated quantities by the AMBER and CHARMM force fields for the phosphorylated amino acids over a wide range of properties related to their conformational ensembles, such as NMR 3 J couplings, intramolecular hydrogen bonding propensities, conformational preferences, and more; inconsistencies in calculated conformational preferences by AMBER and CHARMM for larger IDPs have also been noted by Rieloff and Skepö 53 . This raises questions about the suitability of current force field parameter sets for simulation of these systems.…”

Section: Introductionmentioning

confidence: 99%

“…ForceBalance is used to optimize bonded parameters starting from those created by Homeyer et al 43 for the phosphorylated side chains in order to keep consistent parameters for the backbone atoms, with the nonbonded parameters unmodified from those implemented by Homeyer et al 43 and Steinbrecher et al 45 Detailed potential energy surface comparisons are made between parameters from AMBER ff99SB, 63 which we use as a starting point for the force field optimization, the "FB18" optimized parameters presented in this work and the QM reference data for validation of the energies predicted by the new parameters. Additionally, we compare the new force field to experimental data for blocked dipeptide forms of each of the amino acids parameterized here, similarly to the procedure performed by Vymětal et al 52 These are essentially the simplest phosphorylated systems possible, for which a multitude of data exists, such as 3 J NMR couplings and chemical shifts, intramolecular hydrogen bond propensities, and backbone conformational preferences. [64][65][66] The simple nature of these systems allows for relatively straightforward comparison between MD simulation results and experiment.…”

Section: Introductionmentioning

confidence: 99%

Development and validation of AMBER-FB15-compatible force field parameters for phosphorylated amino acids

Stoppelman

Nerenberg

et al. 2021

Preprint

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Phosphorylation of select amino acid residues is one of the most common tools for regulating protein structure and function. While computational modeling can be used to explore the detailed structural changes associated with phosphorylation, most molecular mechanics force fields developed for the simulation of phosphoproteins have been noted to be inconsistent with experimental data. In this work, we parameterize force fields for blocked dipeptide forms of the phosphorylated amino acids serine, threonine, and tyrosine using the ForceBalance software package with the goal of improving agreement with experiment for these residues. Our optimized force field, denoted as FB18, is parameterized using high-quality \textit{ab initio} potential energy scans and is designed to be fully compatible with the AMBER-FB15 protein force field. When utilized in MD simulations together with the TIP3P-FB water model, we find that FB18 consistently enhances the prediction of experimental quantities such as $^3J$ NMR couplings and intramolecular hydrogen-bonding propensities in comparison to previously published models. As was reported with AMBER-FB15, we also see improved agreement with the reference QM calculations in regions at and away from local minima. We thus believe that the FB18 parameter set provides a promising route for the further investigation of the varied effects of protein phosphorylation.

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AMBER and CHARMM Force Fields Inconsistently Portray the Microscopic Details of Phosphorylation

Cited by 26 publications

References 84 publications

An Inherent Structural Difference Between Serine and Threonine Phosphorylation: Phosphothreonine Prefers an Ordered, Compact, Cyclic Conformation

An Inherent Structural Difference Between Serine and Threonine Phosphorylation: Phosphothreonine Prefers an Ordered, Compact, Cyclic Conformation

A predictive coarse-grained model for position-specific effects of post-translational modifications

Development and validation of AMBER-FB15-compatible force field parameters for phosphorylated amino acids

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